JP2019084869A - Magnet wheel and drone with magnet wheel - Google Patents

Abstract

To provide a magnet wheel for traveling with magnetic attraction, especially a magnet wheel for traveling with magnetic attraction for driving a suspension for driving a drone.SOLUTION: In a magnet wheel in which a magnet is disposed around an axle, the axle and, a rubber ring, a magnet fixing plate, a yoke and an outside surface plate are arranged toward both sides from the center of the axle. The rubber ring is provided with a plurality of magnet insertion holes. Optional number of magnets are inserted into the magnet insertion holes.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a magnet wheel. In particular, the present invention relates to a magnet wheel suitable for traveling on the lower surface or the vertical surface of a ferrous structure by magnetic attraction.

In developed countries such as Japan, anti-aging measures are required for bridges and elevated bridges, and in particular, examination of inspection methods for the lower surface and vertical surface is required.
As the inspection means, visual observation from below, visual observation by moving with a work vehicle such as an aerial work vehicle, visual observation by a suspension scaffold, or photographing is used.
Recently, the adoption of a drone equipped with a shooting method is being considered.

For example, in Patent Document 1 (Japanese Patent Application Laid-Open No. 3-260206), a lifting device is mounted on the roof of a vehicle so as to be movable in the front and rear direction, and a base provided at the upper end of the lifting device is horizontally mounted. The proximal end of the foldable link mechanism is horizontally pivotably connected, and a sensor base is provided rotatably at the distal end of the link mechanism in the vertical and horizontal directions, and from this laser head to the laser head Having supported a laser measurement device comprising a laser scanner that scans incident laser light upward with a predetermined swing width and a light detection sensor that detects the amount of reflected laser light scanned by this laser scanner A characteristic viaduct check system has been proposed.
Patent Document 2 (Japanese Unexamined Patent Publication No. 2017-95959) discloses an inspection device in which an inspection device is mounted on the lower surface side by turning a wire around the entire bridge or the like. And this document points out that there is a problem in the use of drones as follows.
When carrying out an appearance inspection of a structure, it may be difficult to arrange an operator or a camera near the surface to be inspected. In such a case, a scaffold for inspection or the like may be constructed, but the construction of the scaffold takes time and labor. Also, it may be difficult in the first place to build a scaffold, like structures on water. Therefore, in recent years, it has been considered to use a flying object or the like called a drone capable of flying by remote control or autonomous control for inspection of a structure. By flying a flying object equipped with a camera or the like, it is considered that an inspection of a place where a worker or the like can not easily approach can be performed without the need to construct a scaffold or the like.
However, due to the effects of weather, such as rain and wind, it is difficult for the flying object to stabilize its attitude during flight, and the accuracy of the inspection position on the structure tends to be reduced. In addition, in a place surrounded by a structure, position accuracy by a satellite ranging system such as GPS is likely to be deteriorated. Under these circumstances, various limitations are considered to exist in the inspection of a structure by a flying object.
On the other hand, since the inspection robot disclosed in Patent Document 2 is physically attached to the structure, the stability of the attitude becomes higher than that of the flying object, and the accuracy of the inspection position can be easily improved. The operation of the inspection robot does not require a high level of skill like the maneuvering of a flying object, and since the main body is suspended by a plurality of wire arms, it is easy to prevent the main body from falling It is very safe.
For example, in Patent Document 3 (Japanese Patent Laid-Open No. 2017-95980), which is an example of an elevated road surface, a floor slab is mounted on the upper surface of an H-shaped steel girder member installed on a bridge pier.
Patent Document 4 (Japanese Patent Laid-Open No. 2017-138162) discloses a drone used for an inspection system for capturing an image of a structure while flying.
Patent Document 5 (Japanese Unexamined Patent Publication No. 2017-54486) discloses an inspection drone provided with an infrared camera.
Patent Document 6 (Japanese Unexamined Patent Publication No. 2017-89211) discloses an inspection drone apparatus including a magnet for adsorption and fixation, a roller for movement, and a ladder for releasing the adsorption.

Patent Document 7 (Japanese Patent Laid-Open No. 9-267606) comprises an axle, permanent magnets and wheels disposed around the axle, and a gap is provided between the permanent magnet and the axle, and the wheel A nonmagnetic member and / or a weak magnetic member is disposed on the inner circumferential portion of the magnetic sensor, and a ferromagnetic member is disposed on the outer circumferential portion of the wheel. A magnet wheel with low mechanical noise is disclosed.
Patent Document 8 (Japanese Patent Application Laid-Open No. 10-157403) A magnet wheel disposed around an axle and provided with a permanent magnet and a yoke, wherein the yoke through which the generated magnetic flux from the permanent magnet passes is a curved attraction surface Discloses a magnet wheel capable of stable traveling on a curved traveling path provided with
In Patent Document 9 (Japanese Patent Laid-Open No. 2016-78466), the vehicle body base 7 and the wheel main body portion 9 rotatably provided on the vehicle body base 7 and the wheel body portion 7 in order to avoid the shortage of the magnetic attraction force. The flat portion 13 or the linear ridge portion 15 formed at the end of the flat portion 13 is provided with the rotation of the wheel main body portion 9 to form the flat portion 13 or the linear ridge portion 15 on the structure 17. A magnetic adsorption traveling vehicle 3 is disclosed which has a magnet 11 provided on the outer periphery of the wheel main body 9 so as to adsorb.

Japanese Patent Application Laid-Open No. 03-260206 Unexamined-Japanese-Patent No. 2017-095959 Unexamined-Japanese-Patent No. 2017-095980 JP, 2017-138162, A Unexamined-Japanese-Patent No. 2017-054486 JP, 2017-089211, A Japanese Patent Application Publication No. 09-267606 JP 10-157403 A JP, 2016-078466, A

  An object of the present invention is to provide a magnet wheel for magnetically attracted traveling. In particular, it is an object of the present invention to provide a magnet wheel for magnetically attracting traveling for suspension drive for drone drive.

  The present invention is a magnet wheel suitable for traveling by attracting to the iron portion of the undersurface or wall surface of an elevated or bridge by magnetic force.

The present invention is summarized as follows.
1. In a magnet wheel in which a magnet is arranged around an axle,
The axle and rubber ring, magnet fixing plate, yoke and outer side plate are arranged from the center of the axle to both sides,
A plurality of magnet insertion holes are provided in the rubber ring, and an arbitrary number of magnets are inserted in the magnet insertion holes.
2. The rubber ring is a laminated structure of thin rubber rings,
The yoke is characterized in that a thin yoke plate is laminated. Magnet wheel described.
3. The diameter of each element arranged around the axle is characterized in that the rubber ring is the largest diameter, the yoke is the smallest diameter, and the magnet fixing plate and the outer side surface plate are the intermediate diameter. Or 2. Magnet wheel described.
4. A female screw portion provided in the enlarged diameter portion of the axle and a joint hole provided in the outer side surface plate are joined with a screw. ~ 3. Magnet wheel according to any of the.
5. Drive installed 1. ~ 4. Magnet wheel according to any of the.
6.1. To 5. A drone fitted with a magnet wheel listed in one of the.

1. The present invention has realized a magnet wheel suitable for traveling by magnetically attracting to an iron part.
Since the magnet can be inserted and fixed in the hole provided in the rubber ring, the magnet fixing means such as bonding is unnecessary. In addition, the rubber ring generates the traction necessary to overcome the step formed in the joint such as H-shaped steel.
2. Since the rubber ring and the yoke are thin, the magnetic force adjustment and the width of the magnet wheel can be adjusted by adjusting the number of sheets used. In addition, since the thin plate is used including the magnet fixing plate and the outer side plate, it is easy to change the wheel diameter. By changing the wheel diameter, it is easy to cope with the height of the projection on the iron portion which is the traveling surface. By using a laminated structure, the manufacturing cost of the individual parts can be suppressed, and the design change can be coped with by changing the number of members, so that the cost can be reduced as a whole.
3. Since the yoke had the minimum diameter, the yoke was prevented from coming into direct contact with the adsorption iron portion. There is a risk that the surface of the iron member will be damaged if the yoke directly contacts the iron member which is the adsorptive surface, and the coating such as the coating of the iron part is peeled off, causing rust and corrosion. It should be avoided that the aging investigation act causes aging.
In the magnet wheel of the present invention, although the rubber surface is usually the contact surface, even when the rubber surface is recessed, the magnet fixing plate and the outer surface plate contact the attracted iron member, so that the yoke can be prevented from contacting.
4. There is no need to individually fix the rubber ring, the magnet fixing plate, the yoke, the outer face plate and the respective plates laminated with screws from the outer face plate to the axle without having to fix them individually, the number of yokes, rubber It is easy to change the number of rings manufactured.
5. By providing the drive device on the magnet wheel, it is not necessary to receive the driving force from the main body side to which the magnet wheel is attached.
6. By attaching the magnet wheel to the drone, measurement data can be obtained in a state where the magnet wheel is adsorbed to the lower surface or the like of the elevated which is difficult to access. Since measurement is not performed in unstable flight conditions, it is possible to simplify the process of correcting the data.

Schematic of magnet wheel Figure showing an example of a magnet wheel Example of magnet wheel with drive Figure showing an example of a magnet wheeled drone Figure showing an example of a magnet wheeled drone with camera Figure showing an example of the inspection point (bridge bottom) Diagram showing a conventional example of a magnet wheel (Patent Document 7) The figure which shows the prior art example provided with the magnet for adsorption fixation, and the roller for movement (patent document 6)

The present invention is a magnet wheel. Bridges, which are social infrastructures, elevated railways and railways, iron towers for power transmission lines, etc., are aging and need to be checked immediately. The backs of bridges and elevated tracks, towers, etc. are not easily accessible, and the use of climbing or gondolas is dangerous. In addition, skilled workers are also short-handed. Although a method of flying a drone or the like to obtain inspection information has been considered, the flight attitude does not have a constant inclination or approach distance, so it is difficult to correct acquired data.
The present invention proposes a magnet wheel suitable for traveling on the lower surface or vertical surface of an iron structure by magnetic attraction.
In the present invention, a rubber ring, a magnet fixing plate, a yoke, and an outer side plate are disposed from the center toward both sides of an axle of a magnet wheel, and the rubber ring is provided with a plurality of magnet insertion holes. , An arbitrary number of magnets are inserted. Since the magnet can be inserted and fixed in the hole provided in the rubber ring, the magnet fixing means such as bonding is unnecessary. The number of magnets to be inserted can be changed. The magnet fixing plate is provided with the same magnet insertion hole as the rubber ring. The magnets are arranged on the left and right sides of the magnet fixing plate to stabilize the magnets. In addition, the rubber ring can be used as a cushion over a step formed in a joint such as H-shaped steel. As the rubber, natural rubber, resin rubber such as urethane is used. In this example, urethane rubber is used.
H-shaped steel is often used for girder materials for elevated bridges and bridges. As schematically shown in FIG. 6, the H-shaped steel is constituted by the web W of the vertical member and the flange F of the flat material, and a plurality of H-shaped steels are connected to constitute a girder. A joint plate J is provided at the connection portion, and is joined to the flange portion by a screw. In the H-shaped steel girder material, a level difference corresponding to the thickness of the joint plate J is generated. Further, the joint plate J joined to the flange can not be provided with a screw by the web in the central portion of the H-shaped steel and is flat, and the flat portion through which the magnet wheel can pass is only the central portion.
Since the magnet wheel of the present invention has a rubber ring, it is easy to get over this step.

According to the present invention, the width of the magnet wheel can be adjusted by making the rubber ring and the yoke as thin plates and changing the number of laminated layers. Also, the magnetic force can be adjusted. The weight of the magnet wheel can also be adjusted by adjusting the number of sheets.
Moreover, the diameter of a magnet wheel can also be adjusted by providing the thin layer board from which a diameter differs. For the diameter change, the magnet fixing plate and the outer side plate also have diameters corresponding to a plurality of types. For the magnet fixing plate and the outer side plate, for example, a synthetic resin plate such as polycarbonate is used.
By this configuration, it is possible to easily adjust to a magnet wheel of a size that can avoid the height of the step portion and the obstacle on the traveling path.
The diameter of the magnet wheel is also important for securing a space for attaching a measurement device for inspection to a drone or the like described later.

In the magnet wheel, the maximum diameter of the rubber ring, the minimum diameter of the yoke, and the intermediate diameter of the magnet fixing plate and the outer side surface plate prevent the yoke having the minimum diameter from directly contacting the iron portion to be attracted.
As the magnetic member, since the yoke is close to the iron portion of the attracted surface, contact is not made, but the diameter difference between the yoke diameter and the magnet fixing plate or the outer surface plate is made small to approach the attracted surface. Design to.
With the rubber ring as the largest diameter, the contact surface of the magnet wheel becomes a rubber surface. The rubber surface has elasticity and friction to stabilize the running. If the contact surface of the magnet wheel is an iron member, the adsorption surface is also an iron member, so the friction decreases and the running stability is lost. When the iron members are in contact with each other, the adsorptive surface may be damaged. In the actual machine test in which the rubber surface is not provided, peeling of the paint, etc. was found to occur particularly at the time of operation control such as course change.
When the yoke was in contact with the iron portion, the phenomenon of idling at the step portion was observed, and when the diameter of the yoke was reduced, this could be resolved.
In addition, by fixing the components attached to the axle to the axle from the outer surface plate to the axle with a bolt, they can be integrated without being attached to the axle, and adjustment of each member can be facilitated.
Further, by providing the drive device on the magnet wheel, it is not necessary to change the drive system provided on the main body side to which the magnet wheel is attached.
In addition, an operation control system can be provided on the magnet wheel. By disposing a camera, a laser sensor and the like on the front side of the magnet wheel, it is possible to understand the surrounding situation and the obstacle, the distance traveled and the like, and to enable self-sustaining traveling.

The magnet uses a permanent magnet. For example, known permanent magnet materials such as rare earth magnets and ferrite magnets, alnico magnets, Mn-Al-C magnets, and the like. Examples of the rare earth magnets, R-Fe-B system, R-C ₀₅ based, R ₂ C ₀₁₇ system (R is one or more rare earth elements including Y) is.
For example, permanent magnets of R-Fe-B system (R: one or more kinds of rare earth elements such as Nd and Pr) can be used.
The yoke uses a known soft magnetic material. For example, known steel materials such as pure iron, soft iron, ordinary steels such as carbon steel and low alloy steel, special steels for construction, tool steels, ferritic and martensitic stainless steels and the like can be mentioned. In addition, known iron-based castings such as cast iron and cast steel can also be mentioned. Known soft ferrites such as Mn-Zn ferrite and Fe-Ni alloys such as permalloy, Fe-Ni-Co alloys such as Kovar, and powders of these known soft magnetic materials as thermoplastic resin or thermosetting resin Bonded bonded soft magnetic materials can also be used.

The inspection device in which the magnet wheel is attached to a main body such as a drone can travel by magnetically attracting to the back surface of an elevated bridge or a bridge or to an iron material such as a steel tower. The distance between the measurement sensor and the member to be inspected can be stabilized, and accurate data can be obtained.
In particular, when traveling by magnetically adsorbing to a H-shaped steel or a narrow steel material for a steel tower, it is possible to arrange two magnet wheels in tandem and select a place free of obstacles such as the head of a bolt. Since the number of laminations of thin plates can be changed, the width of the magnet wheel can be adjusted according to the travelable width. In addition, since the diameter of the magnet wheel can be changed according to the protrusion or the sensor device present on the traveling path, it is possible to flexibly cope with the survey target. Further, in the magnet wheel of the present invention, since the rubber member is in contact with the traveling steel material, it is possible to easily get over the step portion of the joining plate in the connection portion of the steel material.

A camera for controlling the main body or a distance sensor can be attached to the drone or the like, and automatic control can be performed based on the distance between the image information and the obstacle. In addition, video information can be output to a control monitor for wired control.
In particular, by setting the drone maneuver as manual control and including the power line in the cable and supplying power from the ground, it is not necessary to mount the drone battery and the magnet wheel battery on the drone body. The weight of the projectile can be reduced and the load on the magnet wheel can be reduced. The length of the cable is sufficient because the height of the bridge or elevated is usually several tens of meters.
In addition, by weakening the rotational speed of the rotor of the drone during magnetic attraction travel, the drone contacts an uneven part, an obstacle, or the like, thereby providing an assisting force for avoiding the risk that the magnet wheel is likely to separate.
As the sensor for the measuring device, an imaging device, a sound collecting device, a laser distance sensor or the like can be used.

The example of the magnet wheel A of this invention is shown based on FIG. 1, FIG. The outline of a magnet wheel is shown in FIG. 1, and the example of a magnet wheel is shown in FIG.
FIG. 1 is a perspective view of a magnet wheel A in which the outer side surface plate is removed to make it easy to understand.
A disk-shaped rubber ring 1, a magnet fixing plate 2, a yoke 3, and an outer side plate 4 are mounted on an axle 9. Magnet insertion holes 12, 12, ... are radially formed in the rubber ring 1, and an arbitrary number of magnets 5 are inserted into the magnet insertion holes.
Since the magnet 5 is inserted into the magnet insertion hole 12 provided in the rubber ring 1 and stabilized, no jig for fixing the magnet is necessary, and it is possible to easily select the magnet replacement and which insertion hole to use. .
Since the contact surface of the magnet wheel A is the rubber surface 13, it contacts softly the contact surface, and it is easy to get over the step portion of the magnetic attraction traveling surface.

A front view (a), a side view (b) and a cross-sectional view (c) of the magnet wheel A are shown in FIG.
The arrangement of each member is well shown in the sectional view (c). Disk-like members are stacked on the axle 9 from the center to the outside. There are four thin rubber rings 11 in the central part, and on both sides there is a magnet fixing plate 2 having a diameter smaller than that of the rubber thin ring 11, and on its outer side a thin yoke having a diameter slightly smaller than that of the magnet fixing plate 2. There are four plates 31 and the outer side plate 4 having the same diameter as that of the magnet fixing plate 2 is laminated on the outermost side, and a screw 93 for fixing these laminated bodies to the axle is shown on the axle 9 of the outer side plate 4. It is attached.
The surface where the magnet wheel comes in contact with the attracted surface has the largest diameter and is the outer peripheral surface of the elastic rubber ring.
The magnet 5 is a permanent magnet and is inserted into the magnet insertion hole 12 provided in the thin rubber ring 11. The magnet fixing plate 2 is also provided with an insertion hole through which the magnet passes, and the magnet 5 contacts the yoke which is a magnetic body. The hole formed in the magnet fixing plate may be formed larger than the magnet 5. The magnet 5 may be an integral body or may be laminated with thin film rings according to the thickness of the thin rubber ring 11.
A central portion of the magnetic wheel axle 9 is an enlarged diameter portion 91 having a large diameter, and a female screw portion 92 is formed on the side surface of the expanded diameter portion 91. A screw 93 is screwed into the female screw portion 92 from the outer side plate 4 to clamp and fix the whole. A through hole of a screw 93 is formed in the outer side plate 4, the yoke 3 and the magnet fixing plate 2. The axle 9 has a cylindrical diameter, and the inner surface is provided with a key coupling notch 95 for coupling with the shaft, and the outer surface is provided with a bearing recess 96. The magnet wheel is attached to the frame via a bearing, and freely pivoted or driven through a shaft through an axle.
Further, in this example, the number of thin rubber rings 11 is four as the minimum number of laminated sheets, and is an example that can be increased. Even when the number of thin rubber rings and the number of thin yokes are increased, the thin rubber rings are tightened and fixed with screws 93 through the magnet fixing plate and the thin yoke plate by the outer side plate. Become.

  The magnet wheel A can adjust the width of the magnet wheel and the magnetic force of the magnet by adjusting the number of thin rubber rings and the number of thin yoke plates. Moreover, the rubber ring 1, the magnet fixing plate 2, the yoke 3, and the outer surface plate 4 are made of a plurality of combinations of different diameters, which facilitates design change of the magnet wheel diameter.

An example of the drive control device-equipped magnet wheel B is shown in FIG.
The magnet wheel A is mounted on a frame 63 disposed in a U-shape on the side and bottom of the magnet wheel A, and the frame 63 having the steering servomotor 62 mounted on the bottom frame 63a of the frame 63 is controlled to rotate. Adjust the angle and steer.
The axle 9 of the magnet wheel A is rotatably attached to the side frame 63b via a bearing.
The gear head 65 is attached to one of the side frames 63b, and the travel motor 61 is attached. The output shaft of the traveling motor 61 penetrates the pipe-shaped axle 9 of the magnet wheel A and is keyed to the axle and driven by the traveling motor 61.
The control frame 63 is connected to the main body attachment portion 67 and attached to a movable body such as a drone. The steering servomotor 62 provided on the lower side of the bottom surface frame 63 a of the frame 63 controls the rotation of the frame 63 with the central axis of the drive wheel A as the steering central axis 66 and steers.
Further, an example of a traveling camera and a laser sensor attached to the magnet wheel is shown in FIG. A traveling camera 71 and a laser sensor 72 are mounted in front of the drive-equipped magnet wheel B. By attaching this, the distance to the front bridge pier or the distance to the rear bridge pier can be found. The side edge of the flange of H-shaped steel etc. is known, and the traveling path can be confirmed.

This is an embodiment in which a magnet wheel is mounted on a drone.
This is an example in which the magnet wheel of the first embodiment or the second embodiment is attached to the upper surface of the drone main body and magnetically attracted to the iron portion of the undersurface of the elevated or bridge to travel. It is a drone equipped with a main body and a rotor, and is a suspended drone that travels by magnetically attracting to the iron part of a building. This drone is suitable for mounting inspection equipment for inspection.
The objects to be adsorbed are the H-type steel, box-type steel, steel girder, iron part of the bridge pier, tunnel inner surface iron part, etc., which is the lower surface of the building. The building is suitable for inspection of elevated areas, bridges, tunnels, buildings, warehouses, exercise facilities, etc. in areas that can not be reached and can not be seen from above.
The inspection equipment for inspection is an imaging device such as a camera, a microphone picking up a hitting sound or traffic vibration, an infrared camera, a laser range finder, and the like.
The drone can be operated wirelessly or by wire. The drone has another camera attached to the main unit to obtain ambient information during flight or magnetic attraction. When traveling on a flange or the like of H-shaped steel, the flange can be detected for automatic traveling. Also, the information from this camera can be copied onto the monitor of the controller and operated.

In this embodiment, two magnet wheels are arranged in tandem. H-shaped steel is often used for elevated and bridge girders. Because the two wheels are hanging, the attitude is stabilized in the vertical direction. Since the airframe is stable, the attitude of the measuring device to be mounted is stable, and high quality data can be obtained.
Furthermore, as shown in Patent Document 1, Patent Document 3, and FIGS. 6 (a) and 6 (c), the flange of H-shaped steel is narrow, and the head of the bolt protrudes to the steel plate for joining, and a place where magnetic attraction is possible. Is in the middle, so it is suitable to use two wheels in series.
In the present embodiment, when the rotor is rotated weakly, separation can be prevented even if the adsorptive power is weakened due to a step with the steel plate for bonding.
The drone rotor is mounted on the lower side so as not to interfere with the magnet wheel and the measuring device mounted on the upper surface side of the main body.
The drive source of the drone is supplied from the battery or the ground by a wire cable.
Operation control of the drone is by radio control or wired.
In the inspection of the underpass and underpass of the elevated bridge and the height is less than a few tens of meters, wired operation is possible. When wired, the control line, the power line, the control of the measurement device, and the line for measurement data can be integrated to connect the cable to the drone. This makes it possible to reduce the weight of the drone without the need to load the drone with a battery. Since the weight can be reduced, the adsorption by the magnet wheel can be stabilized. Alternatively, the weight limitation of the mounted measuring device is alleviated.
Also, there is no time limit for drones. If the battery runs out during magnetic adsorption, the drone will be in an adsorbed state, making recovery difficult.
The information obtained from the measurement data can also be manipulated while confirming with the monitor, and the operation of the measuring instrument can be performed intensively at the points to be noted.

The example of the drone 100 which mounted | worn the magnet wheel of the present Example 3 is shown in FIG.
In the drone 100, the rotor 120 is attached to a rotor weir 121 which extends horizontally from the main body 110 in the same manner as a normal drone. In the present example, there are six rotors. The leg 130 is attached to the rotor cage 121.
The main body is attached with a cable 180 for operation, power, information and inspection device operation so that operation, operation and power supply can be performed from the ground. In addition, four main body cameras 111 are attached to the main body of the drone, and automatic traveling is possible as well as confirmation of surrounding conditions during flight and adsorption.
Two support members 170, 170 are provided on the upper surface of the main body 110 of the drone 100, the mounting rod 160 is mounted on the supporting member, and the magnet wheel B is mounted on the mounting rod. The magnet wheel B is located above the rotor 120 and disposed in a non-buffering positional relationship. Also, in this example, the mounting rod 160 is straight and set to be longer than the main body, and the mounting position of the magnet wheel B can be adjusted in the longitudinal direction of the mounting rod.

Further, in this example, a camera 310 is mounted as the inspection device 300. Two struts 220 are attached to the upper surface of the main body 110, and the lateral rib 230 is attached to the struts to form the sensor mounting portion 200. In this example, the camera 310 is mounted on the side of the camera as a sensor. Furthermore, although not described in the drawings, a laser distance meter is provided at the front and back of the main unit, and the laser distance meter grasps the distance between the front and rear bridge piers, and locates the drone between the bridge piers. It accurately identifies the location being measured. For example, a camera or a laser sensor shown in FIG. 3C is attached to the magnet wheel. By attaching this, the distance to the front bridge pier or the distance to the rear bridge pier can be found. The side edges of the H-shaped steel flange etc. can be recognized and autonomous operation can be performed.
In this example, the camera 310 for inspection is lower than the tip of the magnet wheel B so as not to hinder the attraction of the magnet wheel. The crossbar 230 crosses the upper side of the mounting bar 160, but may pass through the lower side or may be divided into right and left. The important thing is to make the inspection equipment be lower than the suction height of the magnet wheel. Depending on the type of inspection equipment, adjust the diameter of the magnet wheel to secure an allowance for mounting the inspection equipment.
In this example, although the tip of the horizontal weir 230 is located outside the rotor 120, an apparatus for traveling and checking H-shaped steel girder members is assumed, and between the girder and the girder There is a space for the height of the H-shaped steel, and even if it is slightly inclined to the left and right, the camera does not touch and the girder gap is set to a length that can fit within the shooting range.

  FIG. 5 shows a drone test machine of this embodiment. FIG. 6 shows a test state in which an adsorption traveling and a camera are operated on the lower surface of an H-shaped steel in which a test drone is imitated on a bridge girder or an elevated girder material. In this test machine, a 20 mm thick bonding plate could be run through.

1 ··· Rubber ring 11 ··· Thin rubber ring 12 ··· Magnet insertion hole 13 ··· Rubber surface

2 ・ ・ ・ Magnet fixing plate

3 ・ ・ ・ Yoke 31 ・ ・ ・ Thin thickness yoke plate

4 ・ ・ ・ outside face plate

5 ・ ・ ・ Magnet

6 Travel driving mechanism 61 Travel motor 62 Steering servomotor 63 Frame 63a Bottom frame 63b Side frame 65 Gearhead 66 Steering central shaft 67 ... Body attachment

71 · · · Camera for traveling 72 · · · Laser sensor

9: Axle 91: Expanded diameter portion 92: Female thread portion 93: Screw 94: Shaft 95: Key joint notch portion 96: Bearing recessed portion

100 · · · drone 110 · · body 111 · · body camera 120 · · · rotor 121 · · rotor 130 · · leg 150 · · travel device 160 · · · · mounting rod 170 · · support member 180 · · · cable

200 · · Sensor mounting portion 220 · · Strut 230 · · · 杆

300 · · Inspection equipment 310 · · Camera

A: Magnet wheel B: Magnet wheel with drive controller F: Flange H: H-shaped steel W: Web J: Bonding plate

Claims (6)

In a magnet wheel in which a magnet is arranged around an axle,
The axle and rubber ring, magnet fixing plate, yoke and outer side plate are arranged from the center of the axle to both sides,
A plurality of magnet insertion holes are provided in the rubber ring, and an arbitrary number of magnets are inserted in the magnet insertion holes. The rubber ring is a laminated structure of thin rubber rings,
The magnet wheel according to claim 1, wherein the yoke has a configuration in which thin yoke plates are stacked. The magnet wheel according to claim 1 or 2, wherein the diameter of each element arranged around the axle is that the rubber ring is the largest diameter, the yoke is the smallest diameter, and the magnet fixing plate and the outer side surface plate are the intermediate diameters. . The magnet wheel according to any one of claims 1 to 3, wherein a female screw portion provided in an expanded diameter portion of the axle and a joint hole provided in the outer side surface plate are joined with a screw. The magnet wheel according to any one of claims 1 to 4, wherein a drive is attached. A drone equipped with the magnet wheel according to any one of claims 1 to 5.